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Etic nerve activity with high doses of orexin-A increasing WAT SNS

Etic nerve activity with high doses of orexin-A increasing WAT SNS activity and circulating FFAs, whereas a low dose decreases WAT SNS activity and does not stimulate circulating FFAs. These effects of the high dose of orexin A were inhibited by histamine 1-receptor blockade. Collectively, these data suggest orexin A affects sympathetic drive to WAT and consequent lipolysis, but in an apparent inverted `U’ function. In addition to the profound inhibition of SNS/NE-triggered lipolysis by peripheral insulin, as discussed above, central insulin also inhibits lipolysis. Specifically, chronic insulin infusion into the mediobasal hypothalamus of laboratory rats increases WAT lipogenic proteins while simultaneously inhibiting activation of WAT HSL phosphorylation thereby decreasing lipolysis apparently by decreasing the SNS drive to WAT as suggested by decreases in pHSL. Moreover, mice with a neural specific-knockout of insulin receptors have the converse lipid profile, with decreases in lipogenesis and marked increases in lipolysis as suggested by increases in pHSL. The exact neuronal population within the mediobasal hypothalamus responsible for the effects on WAT lipolysis is unknown, but recent studies showing that most AgRP neurons lay outside the blood brain barrier NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript Front Neuroendocrinol. Author manuscript; available in PMC 2015 October 01. Bartness et al. Page 21 leads us and others to speculate that insulin receptors on these neurons may be involved. This also would PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/19848166 explain a possible route of access to the brain for WAT-released leptin as indicated by the hypersensitivity of this population of neurons to leptin as well as the opposing effects of mediobasal infused leptin on lipid metabolism versus insulin. That is, mediobasal hypothalamic leptin infusion decreases lipogenesis, inhibits FA uptake into WAT doing so via the SNS innervation of WAT as both surgical and 6OHDA-induced sympathetic WAT denervation blocks these effects. Mediobasal leptin also increases WAT lipolysis, inferred by pHSL increases, an effect also 1268798 chemical information blocked by sympathetic denervation. NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript 11.1 Role of SNS in fat cell proliferation Despite being the hallmark of obesity, white adipocyte proliferation is studied relatively infrequently compared with the vast literature on white adipocyte differentiation. In 1992, Roy Martin’s laboratory showed that in the c-Met inhibitor 2 presence of NE, cultured rat stromovascular fraction does not exhibit the normal increases in fat cell proliferation. Moreover, application of the -AR antagonist propranolol before NE application disinhibited the proliferation of white adipocytes suggesting the NE inhibition was via the -ARs on the stromal vascular cells destined to become adipocytes. Soon thereafter, Penicaud’s group found in vivo evidence of the role of the SNS/NE in WAT cell proliferation showing that denervation of laboratory rat RWAT triggers an increase in WAT pad mass, DNA and A2COL6, a preadipocyte marker. Independently in our search for the role of the SNS innervation of WAT in lipid mobilization by the SDs in Siberian hamsters, we surgically denervated IWAT unilaterally and sham denervated the contralateral pad in Siberian hamsters with the initial purpose of blocking the short photoperiod-induced lipid mobilization in this species. We found, however, a more remarkable effect. Siberian hamsters remain.Etic nerve activity with high doses of orexin-A increasing WAT SNS activity and circulating FFAs, whereas a low dose decreases WAT SNS activity and does not stimulate circulating FFAs. These effects of the high dose of orexin A were inhibited by histamine 1-receptor blockade. Collectively, these data suggest orexin A affects sympathetic drive to WAT and consequent lipolysis, but in an apparent inverted `U’ function. In addition to the profound inhibition of SNS/NE-triggered lipolysis by peripheral insulin, as discussed above, central insulin also inhibits lipolysis. Specifically, chronic insulin infusion into the mediobasal hypothalamus of laboratory rats increases WAT lipogenic proteins while simultaneously inhibiting activation of WAT HSL phosphorylation thereby decreasing lipolysis apparently by decreasing the SNS drive to WAT as suggested by decreases in pHSL. Moreover, mice with a neural specific-knockout of insulin receptors have the converse lipid profile, with decreases in lipogenesis and marked increases in lipolysis as suggested by increases in pHSL. The exact neuronal population within the mediobasal hypothalamus responsible for the effects on WAT lipolysis is unknown, but recent studies showing that most AgRP neurons lay outside the blood brain barrier NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript Front Neuroendocrinol. Author manuscript; available in PMC 2015 October 01. Bartness et al. Page 21 leads us and others to speculate that insulin receptors on these neurons may be involved. This also would PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/19848166 explain a possible route of access to the brain for WAT-released leptin as indicated by the hypersensitivity of this population of neurons to leptin as well as the opposing effects of mediobasal infused leptin on lipid metabolism versus insulin. That is, mediobasal hypothalamic leptin infusion decreases lipogenesis, inhibits FA uptake into WAT doing so via the SNS innervation of WAT as both surgical and 6OHDA-induced sympathetic WAT denervation blocks these effects. Mediobasal leptin also increases WAT lipolysis, inferred by pHSL increases, an effect also blocked by sympathetic denervation. NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript 11.1 Role of SNS in fat cell proliferation Despite being the hallmark of obesity, white adipocyte proliferation is studied relatively infrequently compared with the vast literature on white adipocyte differentiation. In 1992, Roy Martin’s laboratory showed that in the presence of NE, cultured rat stromovascular fraction does not exhibit the normal increases in fat cell proliferation. Moreover, application of the -AR antagonist propranolol before NE application disinhibited the proliferation of white adipocytes suggesting the NE inhibition was via the -ARs on the stromal vascular cells destined to become adipocytes. Soon thereafter, Penicaud’s group found in vivo evidence of the role of the SNS/NE in WAT cell proliferation showing that denervation of laboratory rat RWAT triggers an increase in WAT pad mass, DNA and A2COL6, a preadipocyte marker. Independently in our search for the role of the SNS innervation of WAT in lipid mobilization by the SDs in Siberian hamsters, we surgically denervated IWAT unilaterally and sham denervated the contralateral pad in Siberian hamsters with the initial purpose of blocking the short photoperiod-induced lipid mobilization in this species. We found, however, a more remarkable effect. Siberian hamsters remain.